Advanced search
Publication Cover
Particulate Science and Technology
An International Journal
Volume 38, 2020 - Issue 4
Submit an article Journal homepage
390
Views
2
CrossRef citations to date
0
Altmetric
ARTICLES

Modelling solids friction for fluidized dense-phase pneumatic conveying

Kapil SharmaDepartment of Mechanical Engineering, Laboratory for Particle and Bulk Solids Technologies, Thapar Institute of Engineering and Technology, Patiala, Punjab, India;
,
Soumya. S. MallickDepartment of Mechanical Engineering, Laboratory for Particle and Bulk Solids Technologies, Thapar Institute of Engineering and Technology, Patiala, Punjab, India; Correspondence[email protected]
,
Anu MittalDepartment of Mechanical Engineering, Laboratory for Particle and Bulk Solids Technologies, Thapar Institute of Engineering and Technology, Patiala, Punjab, India;
&
Peter WypychFaculty of Engineering and Information Sciences, University of Wollongong, Wollongong, New South Wales, Australia
Pages 391-403 | Received 20 Dec 2017, Accepted 04 Nov 2018, Published online: 04 Mar 2019

References

  • Barth, W. 1958. Flow processes during the transport of solid particles and liquid particles in gases. with special consideration of the processes of pneumatic conveying. Chemie Ingenieur Technik 30 (3):171–80.
  • Behera, N., V. K. Agarwal, M. Jones, and K. C. Williams. 2013. Modeling and analysis of solids friction factor for fluidized dense phase pneumatic conveying of powders. Particulate Science and Technology 31 (2):136–46.
  • Behera, N., V. K. Agarwal, and M. Jones. 2015. A model of solids friction factor for fluidized dense phase pneumatic conveying. Powder Technology 284:403–10.
  • Cai, L., S. Liu, X. Pan, X. Guiling, Y. Gaoyang, C. Xiaoping, and Z. Changsui. 2014. Comparison of pressure drops through different bends in dense-phase pneumatic conveying system at high pressure. Experimental Thermal and Fluid Science 57:11–19.
  • Chambers, A. J., and R. D. Marcus. 1986. Pneumatic conveying calculations. In The proceedings of 2nd international conference on bulk materials storage and transportation, 49–52. Wollongong, Australia: Australian Society of Bulk Solids and Handling.
  • Chunhui, H., C. Xianmei, W. Jianhao, N. Hongliang, X. Yupeng, Z. Haijun, X. Yuanquan, and S. Xianglin. 2012. Conveying characteristics and resistance characteristics in dense phase pneumatic conveying of rice husk and blending of rice husk and coal at high pressure. Powder Technology 227:51–60.
  • Fehlberg, E. 1969. Low-order classical Runge–Kutta formulas with step size control and their application to some heat transfer problems. NASA Technical Report 314–20.
  • Lu, H., X. Guo, Y. Liu, P. Li, and X. Gong. 2016. Solid-mass flow-rate prediction in dense-phase pneumatic conveying of pulverized coal by a venturi device. Industrial and Engineering Chemistry Research 55:10455–64.
  • Hong, J., and Y. S. Shen. 1994. Flow characteristics of high density continuous conveying of solids. Chemical and Metallurgical Engineering 15:122–8. (in Chinese).
  • Jones, M. G., and K. C. Williams. 2003. Solids friction factors for fluidized dense phase conveying. Particulate Science and Technology 21 (1):45–56.
  • Kaur, B., A. Mittal, P. Wypych, S. S. Mallick, and S. Jana. 2017. On developing improved modelling and scale-up procedures for pneumatic conveying of fine powders. Powder Technology 305:270–8.
  • Klinzing, G. E., R. D. Marcus, F. Rizk, and L. S. Leung. 1997. Pneumatic conveying of solids – a theoretical and practical approach. 2nd ed. Chapman & Hall. doi:10.1007/978-94-015-8981-9.
  • Klinzing, G. E., C. A. Myler, A. Zaltash, and S. Dhodapkar. 1989. A simplified correlation for solids friction factor in horizontal conveying systems based on yang's unified theory. Powder Technology 58 (3):187–93.
  • Li, K., S. B. Kuang, R. H. Pan, and A. B. Yu. 2014. Numerical study of horizontal pneumatic conveying: Effect of material properties. Powder Technology 251:15–24.
  • Mallick, S. S. 2009. Modeling dense-phase pneumatic conveying of powders. PhD diss., University of Wollongong, Australia.
  • Mi, B., and P. W. Wypych. 1994. Pressure drop prediction in low-velocity pneumatic conveying. Powder Technology 81 (2):125–37.
  • Mi, B., and P. W. Wypych. 1995. Investigations into wall pressure during slug-flow pneumatic conveying. Powder Technology 84 (1):91–8.
  • Mills, D. 2004. Pneumatic conveying design guide. 2nd ed. Oxford Publ., Elsevier/Butterworth-Heinemann.
  • Pan, R. 1999. Material properties and flow modes in pneumatic conveying. Powder Technology 104 (2):157–63.
  • Pan, R., and P.W. Wypych. 1992. Scale up procedures for pneumatic conveying design. Powder Handling and Processing 4 (2):167–72.
  • Pan, R., and P. W. Wypych. 1997. Pressure drop and slug velocity in low-velocity pneumatic conveying of bulk solids. Powder Technology 94 (2):123–32.
  • Pan, R., and P. W. Wypych. 1998. Dilute and dense phase pneumatic conveying of fly ash. In The proceedings of 6th international conference on bulk materials storage and transportation, 183–9. Wollongong, NSW, Australia: Australian Society of Bulk Solids and Handling.
  • Ratnayake, C., B. K. Datta, and M. C. Melaaen. 2007. A unified scaling-up technique for pneumatic conveying systems. Particulate Science and Technology 25 (3):289–302.
  • Setia, G., and S. S. Mallick. 2015. Modelling fluidized dense-phase pneumatic conveying of fly ash. Powder Technology 270:39–45.
  • Setia, G., S. S. Mallick, P. W. Wypych, and R. Pan. 2016. Modeling solids friction factor for fluidized dense-phase pneumatic transport of powders using two-layer flow theory. Powder Technology 294:80–92.
  • Setia, G., S. S. Mallick, and P. W. Wypych. 2014. On improving solid friction factor modelling for fluidized Dense-Phase pneumatic conveying systems. Powder Technology 257:88–103.
  • Weber, M. 1981. Principles of hydraulic and pneumatic conveying in pipes. Bulk Solids Handling 1:57–63.
  • Wei, W., G. Qingliang, W. Yuxin, Y. Hairui, Z. Jiansheng, and L. Junfu. 2011. Experimental study on the solid velocity in horizontal dilute phase pneumatic conveying of fine powders. Powder Technology 212 (3):403–9.
  • Williams, K. C., and M. G. Jones. 2004. Numerical model velocity profile of fluidized dense phase pneumatic conveying, 354–8. In The proceedings of 8th international conference on bulk materials storage and transportation. Wollongong, NSW, Australia: Australian Society of Bulk Solids and Handling. July 5–8.
  • Wypych, P. W. 1989. Pneumatic conveying of bulk solids. PhD Diss., University of Wollongong, Australia.
  • Wypych, P. W., O. C. Kennedy, and P. C. Arnold. 1990. The future potential of pneumatically conveying coal through pipelines. Bulk Solids Handling 10:421–7.
  • Wypych, P. W., O. C. Kennedy, and P. C. Arnold. 1990a. Pneumatic conveying of pulverized and crushed R.O.M. coal. In The proceedings of 4th international conference on pneumatic conveying technology, 26–28. Glasgow, Scotland.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.